Bi2Te3 is attracting a renewed interest due to its topological insulator properties; however, even using advanced physical and chemical deposition techniques, the growth of high crystal quality layers on substrates allowing its technological employment, such as Si, is very challenging due to the structural complexity of Bi2Te3. In this work, we present the optimized large-area growth of topological insulator Bi2Te3 epitaxial layers on unbuffered i-Si(111) substrates via metal-organic vapor phase epitaxy (MOVPE), which is of crucial importance for future integration into CMOS-compatible spintronic devices. We found that the key to maximizing the layer quality requires a balanced control of the reactor pressure (P), growth temperature (T), and growth time (t). Within a proper parameter window, the grown Bi2Te3 thin layers are crystalline, stoichiometric, and highly uniform, also at the local scale. They exhibit a rhombohedral crystalline structure, and they are [001] out-of-plane oriented on the i-Si(111) substrate. Low-temperature magnetoresistance measurements revealed clear weak antilocalization effects, demonstrating that the optimized MOVPE-grown Bi2Te3 is a topological insulator, hence opening further possibilities for its technology transfer to innovative devices.

Large-Area MOVPE Growth of Topological Insulator Bi2Te3Epitaxial Layers on i-Si(111)

Kumar Arun;Cecchini Raimondo;Locatelli Lorenzo;Wiemer Claudia;Martella Christian;Nasi Lucia;Lazzarini Laura;Mantovan Roberto;Longo Massimo
2021

Abstract

Bi2Te3 is attracting a renewed interest due to its topological insulator properties; however, even using advanced physical and chemical deposition techniques, the growth of high crystal quality layers on substrates allowing its technological employment, such as Si, is very challenging due to the structural complexity of Bi2Te3. In this work, we present the optimized large-area growth of topological insulator Bi2Te3 epitaxial layers on unbuffered i-Si(111) substrates via metal-organic vapor phase epitaxy (MOVPE), which is of crucial importance for future integration into CMOS-compatible spintronic devices. We found that the key to maximizing the layer quality requires a balanced control of the reactor pressure (P), growth temperature (T), and growth time (t). Within a proper parameter window, the grown Bi2Te3 thin layers are crystalline, stoichiometric, and highly uniform, also at the local scale. They exhibit a rhombohedral crystalline structure, and they are [001] out-of-plane oriented on the i-Si(111) substrate. Low-temperature magnetoresistance measurements revealed clear weak antilocalization effects, demonstrating that the optimized MOVPE-grown Bi2Te3 is a topological insulator, hence opening further possibilities for its technology transfer to innovative devices.
2021
Istituto dei Materiali per l'Elettronica ed il Magnetismo - IMEM
Istituto per la Microelettronica e Microsistemi - IMM
MOVPE
Bi2Te3
Topological insulator
magnetoresistance
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/397012
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